人类Nav1.5的结构揭示了快速失活相关片段是长QT综合征的突变热点

Zhangqiang Li, Xueqin Jin, Tong Wu, Xin Zhao, Weipeng Wang, Jianlin Lei, Xiaojing Pan, N. Yan
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引用次数: 26

摘要

心脏主要Nav通道Nav1.5功能障碍与多种心律失常综合征相关,如3型长QT综合征(LQT3)和Brugada综合征(BrS)。结构-功能关系的建立和疾病变异机制的理解将有助于抗心律失常药物的开发。在这里,我们报道了人类Nav1.5-E1784K的低温电镜结构,这是LQT3和BrS最常见的变异。91个lqt3相关突变的结构图谱揭示了一个涉及快速失活片段的热点。该区域的高密度LQT3突变位点可以用快速失活的“门楔”模型合理地解释,该模型来源于我们之前的结构观察,并得到了大量功能表征的支持。Nav1.5是心脏中主要的电压门控Na+ (Nav)通道。Nav1.5基因突变与多种心脏疾病有关,如3型长QT综合征(LQT3)和Brugada综合征(BrS)。E1784K是一种常见的突变,在LQT3和BrS患者中都有发现。在这里,我们以3.3 Å的总分辨率展示了人类Nav1.5-E1784K变体的低温电镜结构。这种结构几乎与野生型人类结合奎尼丁的Nav1.5相同。分别与LQT3和BrS相关的91点和178点突变的结构图谱揭示了LQT3突变的独特分布模式。BrS突变在结构上均匀分布,而LQT3突变主要聚集在重复序列III和IV中与门控、电压感应、特别是失活有关的片段上。发现了一个涉及快速失活片段的突变热点,并可以用快速失活的“门楔”模型进行机制解释。本文提出的结构分析,重点关注突变对失活和晚期钠电流的影响,为了解Nav1.5通道病变的机制建立了结构-功能关系。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Structure of human Nav1.5 reveals the fast inactivation-related segments as a mutational hotspot for the long QT syndrome
Significance Dysfunction of Nav1.5, the primary cardiac Nav channel, is associated with multiple arrhythmia syndromes, exemplified by type 3 long QT syndrome (LQT3) and Brugada syndrome (BrS). Establishment of the structure-function relationship and mechanistic understanding of the disease variants will facilitate the development of antiarrhythmic drugs. Here we report the cryo-EM structure of human Nav1.5-E1784K, the most common variant shared by LQT3 and BrS. Structural mapping of 91 LQT3-associated mutations reveal a hotspot that involves the fast inactivation segments. The high density of LQT3 mutation sites in this region can be reasonably interpreted by the “door wedge” model for fast inactivation, which was derived from our previous structural observations and is supported by a wealth of functional characterizations. Nav1.5 is the primary voltage-gated Na+ (Nav) channel in the heart. Mutations of Nav1.5 are associated with various cardiac disorders exemplified by the type 3 long QT syndrome (LQT3) and Brugada syndrome (BrS). E1784K is a common mutation that has been found in both LQT3 and BrS patients. Here we present the cryo-EM structure of the human Nav1.5-E1784K variant at an overall resolution of 3.3 Å. The structure is nearly identical to that of the wild-type human Nav1.5 bound to quinidine. Structural mapping of 91- and 178-point mutations that are respectively associated with LQT3 and BrS reveals a unique distribution pattern for LQT3 mutations. Whereas the BrS mutations spread evenly on the structure, LQT3 mutations are clustered mainly to the segments in repeats III and IV that are involved in gating, voltage-sensing, and particularly inactivation. A mutational hotspot involving the fast inactivation segments is identified and can be mechanistically interpreted by our “door wedge” model for fast inactivation. The structural analysis presented here, with a focus on the impact of mutations on inactivation and late sodium current, establishes a structure-function relationship for the mechanistic understanding of Nav1.5 channelopathies.
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